RU2635449C1 - Method for manufacturing humic fertiliser based on biohumus - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: vertical-shape seedling piles with a slope of 2-5° are formed by preparing an organic substrate with the subsequent implementation of a biothermal process in the piles. The substrate is populated with an industrial population of worms at the temperature of +30°C to -20°C, at the population zone temperature from +20°C to +30°C and the worm population density of 500-10,000 pcs. per 1 m² of the pile surface. Between the seedling piles, across, feed insert-piles from fresh livestock and crop production waste are formed, so that they cover all the gaps between the seedling piles. The piles are aligned and watered. After that, the population of worms moves to the feed insert from fresh waste, the waste is contaminated with thermophilic and soil bacteria. After 60-62 days, after processing the waste of feed inserts, the populations of worms with larvae pass to the next feed inserts. The ripe seedling piles are sieved and separated. Empty seedling piles are filled with fresh unfermented livestock and crop production waste. The populations of worms with larvae pass into the last feed inserts, and the previous formed feed inserts become seedling piles. After watering, sieving and separating the seedling piles, liquid biohumus is obtained by mixing 1:1 of a liquid after watering and separated biohumus and activated biohumus. To the latter, vine ash is additionally added at the rate of 2 l per 100 l of the solution, infused for 7-10 days and filtered with the possibility of cutting swollen worm coprolite with filter filaments.

EFFECT: simplifying the technology for processing livestock and crop production waste, improving the quality and reducing the time of a humic fertiliser production.

2 cl, 7 dwg, 7 ex

Description

FIELD OF THE INVENTION

The invention relates to agricultural biotechnology, in particular to a method for the production of humic fertilizer based on vermicompost, and can be used for processing agricultural waste.

State of the art

A known method of producing biohumus, including the preparation of an organic substrate by carrying out a biothermal process in collars, treating the prepared substrate with worms, isolating and processing vermicompost (see Gorodniy N.M. et al. Bioconversion of organic waste in a biodynamic farm, Kiev: Harvest, 1990, p. 111-130).

The disadvantage of this method is that the resulting biohumus has a low quality and long cooking time.

A known method of producing bio-fertilizer, which consists in obtaining vermicompost by vermicomposting agricultural and industrial waste using earthworms and separating vermicompost from worms, using Obolensky hybrid worms obtained by crossing the Red California Hybrid with the Russian population of earthworms from earthworms Eisenia foetida, vermicomposting is carried out at 16-24 ° C for 4-6 months and microorganisms with fungicidal activity are introduced.

In the method, after vermicomposting, vermicompost is kept under natural conditions for ripening.

In the method, microorganisms having fungicidal activity are introduced after separation of the worms or after ripening of vermicompost.

In the method of microorganisms having fungicidal activity, the bacterial strain Bacillus subtilis IPM-215 is used in concentrations of 1 ∙ 10 ⁹ - 1 ∙ 10 ¹² spores per 1 kg of vermicompost.

In the method of microorganisms having fungicidal activity, the culture of the microbial fungus Trichoderma viride Pers ex SF Gray N 16 is used in concentrations of 1 ∙ 10 ⁴ - 1 ∙ 10 ⁸ colony forming units per 1 kg of vermicompost (see Pat. RU No. 2125549, IPC C05F 11 / 08, С05F 11/00, published on January 27, 1999).

The disadvantage of this method used to obtain biofertilizer is that the fertilizer is not sufficiently enriched with biologically active substances of natural origin.

A known method of producing microbiological fertilizer based on vermicompost, including obtaining vermicompost by vermicomposting organic waste using earthworms and introducing microorganisms into biohumus, using organic animal manure previously neutralized to pH 7-8, and as earthworms using hybrid Californian red worm with earthworms Kuban natural population at 10 ⁴ per 1 m ^2, wherein the vermicompost They are carried out for 2–3 months at a temperature of 16–32 ° С under natural conditions; moreover, after the worms are separated from biohumus, a vibrosieve with a pore size of 0.5–1.0 cm is dried to a moisture content of 50–60%, and packaged propylene, make corn extract in an amount of 1.0-5.0% by weight of vermicompost and autoclave for 45-75 min 0.8-1.2 atm, introduce a strain of Bacillus megaterium var. Phosphaticum 319 and maintained until a titer of 8 ∙ 10 ^{10 is} achieved (see Pat. RU No. 2286979, IPC C05F 11/08, C05G 3/04, C12N 1/20, publ., 10.11.2006)

The disadvantage of this method of producing microbiological fertilizer is the complexity of the preparation method.

The closest in technical essence and the achieved positive effect and adopted by the authors for the prototype is a method of producing vermicompost, including the preparation of an organic substrate by carrying out a biothermal process in collars, processing of the prepared substrate with worms, isolation and processing of extra-compost, while the biothermal process is carried out in semicircular collars , the prepared substrate is treated with an industrial population of earthworms, and the processing of vermicompost is carried out by g wounding and holding to full humification.

In the method, the semicircular collar has a radius of 1.1-1.2 m and a base equal to the diameter.

In the method, the raw materials for the preparation of the organic substrate are pre-mixed with the finished organic substrate in a mass ratio of 20: 10: 1.

In the method, vermicompost is granulated at a moisture content of 40-50 wt.%.

In the method, the vermicompost granules are kept until complete humification in the conditions of free air exchange over the entire volume of granules (see US Pat. RU No. 2039029, IPC C05F 3/00, C05F 11/00, published 09.07.1995).

The disadvantage of this method is that the prepared substrate is not sufficiently enriched with biologically active substances.

Disclosure of invention

The objective of the invention is to develop a method for the production of humic fertilizer based on vermicompost, which simplifies and accelerates the processing of animal waste and crop production and production of humic fertilizer, while improving the quality of fertilizer and preserving the industrial population of worms and the accompanying colonies of thermophilic and soil bacteria, which makes it possible solve the technical problem of processing livestock and crop waste, while simultaneously managing by growing production technology, improving the quality and shortening the production time of humic fertilizer, as well as preserving and propagating the industrial population of worms and the colonies of thermophilic and soil bacteria accompanying them.

The technical result that can be obtained using the present invention is to simplify the technology for processing livestock and plant waste, simplify the production of humic fertilizers, improve the quality and reduce the time of fertilizer production, as well as preserve and multiply the industrial population of worms and the accompanying thermophilic and soil bacteria.

The technical result is achieved using a method of producing humic fertilizer based on biohumus, including the formation of seedlings by preparing an organic substrate followed by a biothermal process in the shoulders, populating the prepared enzymatic substrate with an industrial population of worms, pouring seedlings, isolating, sifting, separating and processing vermicompost followed by aging until complete humification, while seedlings are used vertically the first form, with a slope of 2-5 °, a single population of the worms is carried out at a temperature from (+30) ° С to (-20) ° С, while the temperature of the settlement zone is from (+20) ° С to (+30) ° С, with the density of the industrial population of worms 500-10000 pcs. on 1 m ^{2 the} surface of the shoulder, then between the seedling shoulders, across, fodder shoulders are formed from fresh waste from animal husbandry and crop production, so that they cover all the gaps between the seedling shoulders, align the shoulders and their strait, after which the worm population moves to the feed insert from fresh waste, the waste is seeded with thermophilic and soil bacteria, and after a day the feed insert is heated to a temperature of 30-50 ° C, which is maintained by alternating feed inserts and matured races heights and growth of aerobic microorganisms for feeding the worm population, after 60-62 days, after processing the waste of the feed inserts, the worm populations with larvae move to the following feed inserts, and ripened seedling collars are sifted and separated, and then empty seedling collars are filled with fresh unfermented waste from livestock and crop production and worm populations with larvae pass into the last feed inserts, and the previous formed feed inserts become seedlings, and, after the strait a, sifting and separating seedlings, they receive liquid vermicompost by mixing 1: 1 liquid after spilling and separated vermicompost and activated vermicompost, moreover, grapevine ash is added to the latter at the rate of 2 liters per 100 liters of solution, insist for 7-10 days and filtered with the possibility of cutting about the filter thread of the swollen worm coprolite. In the method, the vertical shoulder has a width of 4.0-6.0 m, a length of 2.0-1000 m, a height of 1.5-2.0 m.

Thus, humic fertilizer based on vermicompost obtained using the present invention, allows to increase crop yields by enrichment with biologically active substances of natural origin and at the same time to utilize livestock and plant waste using the proposed method, which has a simplification of production technology, improving quality and reducing time fertilizer production, as well as the conservation and reproduction of the industrial population of worms and escorts colony of thermophilic and soil bacteria waiting for them due to the following factors affecting the rate of waste processing: the density of the industrial population of worms is 500-10000 pcs. on 1 m ^{2 the} surface of the shoulder, while populating or immediately 10000 pcs. 1 m ² in hot seedlings, which are then distributed in an organic substrate or populate a lower density of 500 pcs. on 1 m ^{2 of} the shoulder surface, then the worms lay cocoons and at the end of the second month the required density is reached, and the population of worms is populated once at a temperature of (+30) ° С to (-20) ° С, while the temperature of the settlement zone is from (+20) ° С to (+30) ° С, but it is optimal to carry out a single settlement in the cold season;

- in this case, the optimal temperature regime in seedlings is 30-50 ° C (identified from experiments), which is maintained by alternating feed inserts and mature seedlings, and a large number of thermophilic and soil bacteria in mature collars leads to its rapid colonization of feed inserts and worm populations, which are located in the most comfortable temperature zone for them, depending on the ambient temperature. Winter seedlings 4.0-6.0 m wide, 2.0-1000 m long and 1.5-2.0 m high freeze by 5-10 cm and worm populations descend by the same cm deep into the seedling collar, while low temperatures contribute to more rapid maturation of seedlings, deep penetration of air into it and this leads to an accelerated work of the worm population with the onset of spring;

- seedlings are composed of livestock and crop wastes, and the more diverse the feed for the worm population, the more active and faster the waste is processed, and not only water, but also spoiled juices, molasses, mashed potatoes, vegetable vegetable waste can be used to sprout seedlings , even citrus waste, in the summer period the processing rate of vegetable waste from the fields can reach two weeks and the entire illiquid vegetable returns back to the beds in the form of humic fertilizer. Thus, the conditions for the maximum manifestation of the qualities that the worm possesses are created for the industrial worm population, the main of which is the production of humic fertilizers at high temperature, while the industrial population of worms is grown on an open surface, outdoors, using the thermal energy released by thermophilic bacteria By decomposing carbohydrates, this significantly reduces the cost of production.

The essence of the method of production of humic fertilizer based on vermicompost is as follows:

Forming seedlings of a vertical form, with a slope of 2-5 °, which have a width of 4.0-6.0 m, a length of 2.0-1000 m, a height of 1.5-2.0 m, by preparing an organic substrate with subsequent implementation the biothermal process in the shoulders, the prepared enzymatic substrate is populated with an industrial population of worms, seedlings are spilled, sifting, screening, separation and processing of vermicompost are isolated, followed by complete humification, while once populating the industrial pop is carried out in seedlings yatsii worms at a temperature of (+30) ° C to (-20) ° C, at a temperature from settling zone (+20) ° C and (+30) ° C and industrial population density worms 500-10000 units. on 1 m ^{2 the} surface of the shoulder, then between the seedling shoulders, across, fodder shoulders are formed from fresh waste from animal husbandry and plant growing, so that they cover all the gaps between the seedling shoulders, leveling the shoulders and their strait, after which the worm population moves to the feed insert from fresh waste, the waste is seeded with thermophilic and soil bacteria, and after a day the feed insert is heated to a temperature of 30-50 ° C, which is maintained by alternating feed inserts and matured races of hell beads, and the growth of aerobic microorganisms to feed the worm population, after 60-62 days, after processing the waste of the feed inserts, the worm populations with larvae move to the following feed inserts, and the ripened seedling collars are sifted and separated, and then empty seedling collars are filled with fresh unfermented wastes of animal husbandry and crop production and worm populations with larvae pass into the last feed inserts, and the previous formed feed inserts become seedlings, and, after the spill a, sifting and separating seedlings, liquid vermicompost is obtained by mixing 1: 1 liquid after spilling and separated vermicompost and activated vermicompost; moreover, grapevine ash is added to the latter at the rate of 2 liters per 100 liters of solution, insist for 7-10 days and filtered with the possibility of cutting about the filter thread of the swollen worm coprolite.

Brief description of drawings and other materials

In FIG. 1 shows a method for the production of humic fertilizer based on biohumus, table 1, the result of the analysis of biohumus on the content of humic acids.

In FIG. 2 - the same, table 2, the result of the analysis of vermicompost on the content of gross and mobile forms of elements - phosphorus, nitrogen, potassium.

In FIG. 3 - the same, table 3, the result of bacteriological analysis of the soil.

In FIG. 4 - the same, table 4, dry vermicompost, normative indicators of the mass fraction of dry matter, etc., according to GOST.

In FIG. 5 - the same, table 5, extract from vermicompost, normative indicators of the mass fraction of dry matter, etc., according to GOST.

In FIG. 6 - the same, table 6, the results of the biological activity of vermicompost on the example of cucumber seeds, varieties Palchik.

In FIG. 7 - the same, table 7, the results of microbiological and parasitological indicators.

The implementation of the invention

Examples of specific performance of the method of production of humic fertilizers based on vermicompost.

Three experiments were conducted on a method for the production of humic fertilizers based on biohumus for 60 days (example 1, biohumus 1), for 80 days (example 2, biohumus 2) and for 100 days (example 3, biohumus 3) in order to determine the optimal experience in the production of humic fertilizers by comparing the results of analysis on the content of humic acids; on the content of gross and mobile forms of elements - phosphorus, nitrogen, potassium; bacteriological analysis of the soil; normative indicators of activated vermicompost (vermicompost dry); standard indicators of liquid vermicompost (extract from vermicompost), (see tab. 1-5, 7), and also an experiment was conducted on the example of the seeds of the Palchik cucumber, on their germination with the addition of vermicompost according to the invention (see tab. 6).

Example 1. For the production of humic fertilizer, seedlings are formed using agricultural waste: manure of small and cattle (cattle, cattle), crop waste, then they are colonized by the colonies of the industrial population of Worms of the Southern type and the colonies of thermophilic and soil bacteria accompanying them with fermented with a substrate, while the shoulders form vertical: 4.0-6.0 m wide, 2.0-1000 m long, 1.5-2.0 m high, with a slope of 2-5 °, then between seedlings, across the shoulder form vertical “Feed inserts” are burts from fresh waste from animal husbandry and crop production, so that they cover all the gaps between seedling shoulders and level the shoulders and their strait. Moreover, livestock and crop waste that has not been fermented is used to feed the worm population, while crop waste can be with diseases of a viral and bacterial nature, while the worm, being in a safe environment, moves to the “feed insert” from fresh waste and seeds it with a thermophilic and soil tank By the next day, the “feed insert” is heated to a temperature of 50-55 ° C, which is sufficient for active breakdown of fiber, fungal growth and preservation of vitamins, while the worm begins to actively penetrate the “feed insert”, since a huge the amount of aerobic microorganisms that he eats, thanks to this it is possible to obtain a high concentration of humic substances in the final product, and since the formation of humic substances is a polymerization reaction, this reaction proceeds with heat absorption, namely Therefore, the worm of the Southern Prospector can withstand high temperatures of food media, as it has an internal cooling system. The “feed inserts” are located vertically across the shoulder and therefore fresh air deeply penetrates into them, providing breathing to the worms and bacteria, while in the cold season due to the temperature difference there is a strong heating of the “feed inserts”, but the worm can return back to its seedling the shoulder and at a safe distance wait the extreme temperature rise, and in the summer period due to the small difference in air temperature and the shoulder such heating does not occur, while in the winter period of time does not require constant watering of the shoulders, to the cold air penetrating into the hot core "aft insert", constantly humidifies it, and in the summer piles require weekly watering at least 50 liters of water per 1 m ^2, but due to the fact that the shoulder with the worm warm all year round, in it constantly occurs the process of formation of humic fertilizer. After 60-62 days, having eaten all the food, the worms with young larvae mostly go into the “feed inserts” of the fresh food and then proceed to separation of seedlings, while separation is carried out on drum-type separators with a rotation speed of not more than 1 revolution for 2 s , with a mesh size of 3.2 mm and a working body of 2 m in length and a diameter of 70 cm. The output of separated humic fertilizers is 35% of the total sifted vermiculture, the resulting worm inoculation in the amount of 65% of the total sifted volume is used for formation of new seedlings, when all seedlings are processed, it turns out that the “feed inserts” become seedlings, since the worm is concentrated in them, and instead of the removed seedlings, fresh non-fermented agricultural waste is loaded again and then the worm unfolds and begins to move in the opposite direction, this method of vermicultivation avoids the death of the worm from the human factor, since there is no direct contact and environmental factors, and t kzhe in clamps always have heat and food and the worm is always a choice of temperature and diet. Seedling collars and “feed inserts” do not mix mechanically, this allows you to create lateral environments and, in addition to producing humic fertilizers, constantly breed the worm, as there is a high-nutrient zone in the “feed insert” that provokes an adult worm to lay cocoons in it - once in five to six days, and by the time of separation of the zone of high nutritional seedlings, the worm manages to grow and move to a new “feed insert”. Seedling collars are formed and maintained using a tractor, for example, MTZ 82 with a mounted bucket and a dump truck, and a set of irrigation equipment is used, for example, rubber hoses with a diameter of 40 mm and a total length sufficient to spill the seedling collar farthest from the water intake pump with a capacity of at least 6 m ³ / hour.

When seedling collars ripen, the tractor becomes transverse to their direction and removes the finished vermicompost with a bucket and takes it to the separation shop, leaving the “feed inserts”, and then dumping the truck in reverse direction across the shoulder, filling the vacated space with fresh waste, tipping the body back, when This collar can be up to 1000 m long and their number can be limited only by the power of equipment.

Separated vermicompost is subject to further processing.

During the spilling of seedlings, dark-colored liquid flows out from under them, since when forming seedlings, they are placed with a slope of 2-5 °, so this liquid flows down along the direction of the shoulders and collects into a collector, forming liquid biohumus, and to obtain activated biohumus, the liquid is pumped out with a drainage pump and its separated biohumus is poured in a ratio of 1: 1 in an open container, and grape ash is added to enhance microbial activity to destroy the protein shells of coprolites and their alkalization th vine at the rate of 2 liters per 100 liters of solution, this mass is insisted from 7 to 10 days until the fermentation ceases, then the solution is passed through a milk filter, on the thread of which the swollen worm coprolites are cut, resulting in activated biohumus, in which the coprolites have damage , and therefore it has significantly greater biological value than just separated biohumus, while for the preparation of soil mixtures the recommended ratio of separated biohumus to soil is 1: 6, and for activated biohumus - 1:12 Moreover, the liquid obtained as a result of extraction contains a solution of humic acids and live soil bacteria, which is used for spraying plants as foliar application, and an important distinguishing feature of the resulting product is that it is “vaccinated” from bacterial and viral infections, since soil bacteria get to the “feed insert” with pathogenic microflora and successfully eat it, weakened by high temperature, thus, when biohumus bacteria get on the plant leaf or root The entire pathogenic microflora will be destroyed by the enzymatic system of soil microorganisms tuned to it. The activated biohumus is dried in the open air, packaged in bags and sent for spreading under crops, while the application is made by aggregates for bulk mineral fertilizers at a rate of 2 tons per hectare, and liquid biohumus is used through a sprayer and drip irrigation with a concentration of 1: 6, also activated biohumus, well-dried, can be extruded in a mixture with grain feed and used as a premix for animal husbandry (see Tables 1-5, 7).

Example 2. Carried out analogously to example 1, seedlings are populated with colonies of worms of the Prospector South type and the accompanying colonies of thermophilic and soil bacteria with fermented substrate, followed by spilling of the shoulders, but the production process is held for 80-82 days, the results of the analysis of liquid and activated vermicompost are given in tables 1-5, 7.

Example 3. Carried out analogously to example 1, seedlings are populated with colonies of worms of the Miner Southern type and the accompanying colonies of thermophilic and soil bacteria with fermented substrate, followed by spilling of the shoulders, but the production process is kept for 100-102 days, the results of the analysis of liquid and activated vermicompost are given in tables 1-5, 7.

Example 4. The obtained vermicompost according to examples 1, 2, 3 was tested to determine the germination of seeds of agricultural crops, in particular seeds of cucumber, varieties Palchik, (see table. 6) the length of the stems and roots, as well as the mass of plants under the action of humic fertilizers according to compared to a control using a petri dish. 7 cucumber seeds, pre-treated with a weak solution of potassium permanganate for 30 minutes, are sown in Petri dishes; a double layer of filter paper is pre-treated with biohumate in a concentration of 0.01% in an amount of 10 ml. In parallel, a control sample was laid, where distilled water was used instead of humic fertilizer. Petri dishes with seeds are placed in a thermostat and incubated for 3 days at 29.5 ° C, and then another 6 days in the light at room temperature, after 9 days from the start of the experiment, seed germination is measured, the length of the stems, roots and mass of plants are measured . Calculations of changes in indicators are carried out as a percentage of control shoots. The experiment is carried out in five repetitions. Calculation of normally germinated seeds is carried out twice: after 3 days of incubation and 9 days after germination in the light at room temperature, the length of the roots is measured on a large-scale paper and the average value is calculated. After 9 days of germination, the number of normally germinated seeds in the control sample was 28 pcs. out of 35, in biohumus 1 amounted to 31 pcs., in biohumus 2 amounted to 35 pcs. out of 35 and in biohumate 3 amounted to 32 pcs. from 35. The average length of the primary root in the control sample was 6, 45 cm, in biohumate 1 - 0.38 cm, which is 6.07 cm less than in the control sample, in biohumate 2 - 6.68 cm, which is 0 , 23 cm more than in the control sample, in biohumate 3 - 8.11 cm, and this is 1.66 cm more than in the control sample. The average weight of seedlings in the control was 0.83 g, in biohumate 1 - 1.23 g, which is 0.39 g more than in the control sample, in biohumate 2 - 2.27 g, which is 1.43 g more than in the control, in biohumate 3 - 1.11 g, which is 0.27 g more than in the control. Analyzing the data obtained, we can conclude that during the growing season after processing the seeds of the cucumber with biohumate 1, the plant stem develops well, while the root system lags behind the control sample in growth. Biohumate 2 has good germination performance - 100% germination, contributes to a significant accumulation of mass of seedlings and has high biological activity in increasing the length of the stems. Under the action of biohumate 3, the germination percentage was 85.7%, the vegetative mass was increased by 50% compared with the control, while the high biological activity of biohumate 3 was observed to increase the length of the root system.

Thus, biohumate 1, biohumate 2 and biohumate 3 according to examples 1, 2, 3 (see table. 6) are significantly good compared to the control and their application in agriculture gives good results, namely humic fertilizer in liquid form , and in the activated according to three experiments contains (see tab. 1-5, 7):

- a large number of trace elements in a chelated, easily digestible form for plants;

- bacterial flora up to 20,000 billion colonies in 1 g of biohumus;

- enzymes (phosphatase, catalase), 18 amino acids, vitamins and antibiotics.

In addition, the resulting organic fertilizers do not contain:

- phytopathogenic for plants and phototoxic for soils fungi;

- microorganisms that can cause plant diseases;

- eggs and larvae of helminths, cysts of intestinal pathogenic protozoa.

Biohumus also:

- is protected from leaching and has a prolonged effect, since the nutrients are in organic form;

- characterized by high buffering due to which it does not create excessive concentrations of salts;

- reduces the amount of pesticides in the soil;

- increases the moisture capacity of the soil;

- contributes to the accumulation of humus in the soil;

- helps to reduce nitrates and heavy metals in plants;

- increases the content of available phosphorus and potassium in the soil due to the transformation of elements from inaccessible forms.

Biohumus make:

- under the main tillage, since it is not washed out by precipitation, and also when planting / sowing, since the dry fraction has good flowability;

- as a top dressing using standard sprayers and mineral fertilizer spreaders;

- during pre-sowing treatment of seeds to improve the quality of seedlings, as well as in the preparation of nutritious soils in greenhouse complexes.

The invention in comparison with the prototype and other known technical solutions has the following advantages:

- simplification of the method of production of humic fertilizer based on vermicompost;

- improving the quality and enrichment of biologically active substances of natural origin;

- reduction of production time of humic fertilizer;

- the preservation and propagation of colonies of worms and the colonies of thermophilic and soil bacteria accompanying them;

- increase crop yields;

- environmental cleanliness, as humic fertilizer of natural origin does not contain toxic substances and is safe for use in agricultural production;

- low cost.

Claims (2)

1. A method for the production of humic fertilizer based on vermicompost, including the formation of seedlings by preparation of an organic substrate followed by a biothermal process in the shoulders, populating the prepared enzymatic substrate with an industrial population of worms, sowing seedlings, isolating, sieving, separating and processing vermicompost followed by aging complete humification, characterized in that the seedlings are vertical, with a slope of 2-5 °, a single population of the worms is carried out at a temperature of + 30 ° C to -20 ° C, while the temperature of the settlement zone is + 20 ° C to + 30 ° C, with an industrial population density of worms of 500-10000 pcs. on 1 m ^{2 the} surface of the shoulder, then between the seedling shoulders, across, fodder inserts-shoulders are formed from fresh waste from animal husbandry and plant growing so that they cover all the gaps between the seedling shoulders, leveling the shoulders and their strait, after which the worm population moves towards fodder insert from fresh waste, seeding of waste with thermophilic and soil bacteria, and after a day the feed insert is heated to a temperature of 30-50 ° C, which is maintained by alternating feed inserts and ripening seedlings, and the growth of aerobic microorganisms to feed the worm population, and after 60-62 days, after processing the waste of the feed inserts, the worm populations with larvae pass to the following feed inserts, ripened seedling collars are sieved and separated, then empty seedling collars are filled with fresh unfermented waste from animal husbandry and crop production, and worm populations with larvae pass into the last feed inserts, and the previous formed feed inserts become seedlings, and after olive, sifting and separating seedlings receive liquid vermicompost by mixing 1: 1 liquid after spilling and separated vermicompost and activated vermicompost, moreover, grapevine ash is added to the latter at the rate of 2 liters per 100 liters of solution, insist for 7-10 days and filtered with the possibility of cutting about the filter thread of the swollen worm coprolite. 2. The method according to p. 1, characterized in that the collars are 4.0-6.0 m wide, 2.0-1000 m long, 1.5-2.0 m high.

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